Investigation of Factors Influencing the Photocatalytic Degradation of Pharmaceuticals, a Novel Investigation on Supported Catalysts Using UV-A LEDs as Light Source

Supported titanium dioxide-based photocatalysts were investigated for the degradation of pharmaceuticals under irradiation with UV-A LEDs. Focus of the presented research was placed on the degradation kinetics under different matrix influences and energy flux densities of UV-A radiation. The chemical parameters, pH, orthophosphate, nitrogen concentration and background organic concentration were investigated. The results were evaluated by time-resolved measurement of the concentrations and by calculating and plotting the first-order degradation rate. The results showed clear differences in the rates of degradation of each compound, with diclofenac being the most easily degraded and metoprolol the most resistant. When the influence of energy flux density was examined, a linear relationship between degradation rate and the square root of energy flux density was confirmed. The organic background matrix has a strong influence on the degradation kinetics of the compounds. Nitrogen and orthophosphate slow down the degradation much less than the organic background matrix. Investigating the pH influence, it could be shown that almost no degradation is detected in the basic pH range. The results were illustrated with the help of a radar diagram, which can show all dependencies at a glance.

Automated summary

Supported titanium dioxide-based photocatalysts were used to degrade pharmaceuticals under irradiation with UV-A LEDs. The degradation kinetics under different matrix influences and energy flux densities of UV-A radiation were investigated. The results showed significant differences in the degradation rates of different compounds, with diclofenac being the most easily degraded and metoprolol the most resistant. The energy flux density and organic background matrix have strong influences on the degradation kinetics.